CN201122199Y - DLP zooming projection lens - Google Patents

Abstract

The utility model relates to a DLP zoom projection lens which is mainly characterized in that an optical system in the lens is composed of a focusing group U1 with negative power, a focusing group U2 with negative power, and a compensating group U3 with positive power, and the U1, the U2 and the U3 are arrayed from a screen side to an image plane side along an optic axis, wherein, focusing is realized by shuttling the U1 group along the optic axis and also has a zooming function, zooming is realized by relatively moving the U2 and the U3 from a wide-angle end to a dollyout end along the optic axis, namely, the lens is a asynchronous zooming system, all lenses in the lens adopt spherical lenses with good manufacturability and being suitable for mass production, at the same time, the DLP zoom projection lens also has the advantages of compact structure, low cost, etc.

Description

The DLP Zooming-projection camera lens

Technical field

The utility model belongs to the optical instrument technical field, be on a kind of DLP of being adapted at projector with the matching used Zooming-projection camera lens of non-telecentric light light path.

Background technology

The DLP projection display technique develops rapidly in recent years, and its development trend shows that for the image of realizing giant-screen, high definition, high brightness on short projector distance it can realize that more volume is little, and is in light weight waits product performance.What the core component in the DLP technology mainly adopted is DMD digital picture chip, DMD is the exclusive digital picture chip of grasping and developing of TIX, because its time that emerges is shorter relatively, therefore the patented technology of the DLP projection imaging optical system that is complementary with the DMD technology is few, and existing LCD, what projection lens such as LCOS adopted is telecentric system, can not satisfy the supporting requirement of DMD digital picture chip fully, mainly be because the miniature reflective mirror on the DMD has the upset of 10 or 12 degree with image digital signal when work, to enter the entrance pupil of projection lens and focus on the screen from the upset reflection by micro-reflector of the light beam of lighting source, based on these characteristics, LCD, projection lens such as LCOS often can not satisfy the supporting requirement of DMD digital picture chip.

In addition in the prior art, disclosed Zooming-projection camera lens, a part has been used the aspheric surface technology, promptly improves the image quality of system in the optical system of Zooming-projection camera lens by the adding non-spherical lens.But the application of non-spherical lens is unfavorable for the raising of production efficiency and the reduction of cost to its processing and matching requirements strictness.And in the technology that does not adopt non-spherical lens, in order to reach optical property preferably, the quantity that its technical measures one are combination of lensess is more, generally more than 12, the 2nd, the high-grade optical material of the high index of refraction of the external import of employing, the material of FCD1 that aberration is significantly improved and so on for example, it costs an arm and a leg, manufacturability is poor, working (machining) efficiency and yield rate are very low.In the disclosed a kind of Zooming-projection camera lens of Jap.P. 02120574 technology, the material that is adopted just comprises high-grade materials such as FCD1, LAF, and lens numbers is all more than 12, thereby has problems such as cost height, work efficiency be low too.

The utility model content

The purpose of this utility model provides and a kind ofly can be complementary with DMD digital picture chip, and compact conformation, lens numbers is few, cost is low, production efficiency is high, be fit to the DLP Zooming-projection camera lens of requirements of mass production.

For reaching such purpose, technical scheme that the utility model provides is: the optical system in this Zooming-projection camera lens is made up of the zoom group U2 of focusing group U1 with negative power and negative power and the compensation group U3 of positive light coke; U1, U2, U3 along optical axis from screen side to the picture planar side series arrangement, wherein, focusing is to move forward and backward along optical axis by focusing group U1 to realize, and have zoom function concurrently, zoom is to relatively move along optical axis to the end of dolly-out,ing dolly-back from wide-angle side by zoom group U2 and compensation group U3 to realize that promptly this camera lens is asynchronous zoom system, pancreatic system, the combined focal length of focusing group is f1, the focal distance f 2 of zoom group, both opposite in signs, and satisfy following inequality:

0.55＜|f1/f2|＜0.72

Wherein:

Described focusing group U1 is made up of negative lens L1 and negative lens L2 to the image planes direction from screen side, and its combined focal length is for negative.

Described zoom group U2 is made up of positive lens L3, positive lens L4, negative lens L5 to the image planes direction from screen side, and the total focal length of zoom group U2 is negative.

The front surface (screen side) of positive lens among the described zoom group U2 [L4] is to the bending of image planes direction.

Described compensation group U3 is made up of positive lens L6, positive lens L7, negative lens L8, positive lens L9, positive lens L10 to the image planes direction from screen side, wherein, positive lens L7, negative lens L8 form a cemented doublet group, positive lens L7 in the cemented doublet group by the crown glass with low chromatic dispersion constitute, negative lens L8 is made of flint glass, negative lens L8 is a biconcave lens, cemented surface bends towards the light hurdle, and the total focal length of this compensation group U3 is for just.

Each lens all adopts spherical lens in the described system, and the sum of its lens is 10.

For fully improving the image planes homogeneity, the distance of exit pupil of DLP projection lens will be controlled in the scope that the reflected light angle with the DMD micro-reflector is complementary, in addition, simple and feasible for structure, it is little that the bore of the tail end of DLP projection lens will be tried one's best, to guarantee having enough spaces to make illumination path can obtain effective and reasonable layout.Certainly, the rear portion bore of projection lens can not be too little, and too little bore can not guarantee the F number of total system on the one hand, also may have influence on the illuminance uniformity of imaging surface.

Advantage of the present utility model is:

1, the non-spherical lens of adopting process complexity not in the system, thereby improved the simplification of the processing and the assembling of lens and zoom lens, improved finished product rate and production efficiency, more adapt to and produce in batches.

2, in the satisfaction guaranted image quality, constitute total system with the spherical lens of lesser amt, and adopt conventional optical material, reduce cost of products.

3, the asynchronous zoom by each lens combination moves the consistance that guarantees image quality in the whole focal range, make that like this structure of camera lens is simpler, cost is lower, and keeps the aberration correction of higher level, saved back fixed lens group in the structure again, so structure is more compact.

4, the utility model is provided with the short distance of exit pupil that is complementary with DMD digital picture chip and is significantly improved with luminous energy output and the contrast that guarantees total system.

5, the utlity model has characteristics such as compact conformation, focusing is convenient, projection image is clear.

Description of drawings

Fig. 1 is the structural representation of the utility model zoom lens;

Fig. 2 is the short burnt optical system diagram of the utility model zoom lens;

Fig. 3 is the utility model varifocal mirror head length Jiao's a optical system diagram;

Fig. 4 is that the utility model zoom lens is at short burnt ray trajectory figure;

Fig. 5 is that the utility model zoom lens is at long burnt ray trajectory figure;

Fig. 6 is that the utility model zoom lens is at the short burnt curvature of field and distortion curve figure;

Fig. 7 is that the utility model zoom lens is at the long burnt curvature of field and distortion curve figure;

Fig. 8 is that the utility model zoom lens is at short burnt transfer curve figure;

Fig. 9 is that the utility model zoom lens is at long burnt transfer curve figure;

Figure 10 is that the utility model zoom lens is at short burnt vertical axial aberration curve map;

Figure 11 is that the utility model zoom lens is at long burnt vertical axial aberration curve map;

Figure 12 is that the utility model zoom lens is at short burnt point range figure;

Figure 13 is that the utility model zoom lens is at long burnt point range figure.

Embodiment

Referring to Fig. 1, Fig. 2, Fig. 3, Zooming-projection camera lens of the present utility model, critical piece comprises the lens L1～L10 of trim ring 1, focusing drawtube 2, focusing banking stop 3, guide cylinder 4, curve tube 5, roller guide pin 6, zoom lens barrel 7, compensation lens barrel 8, spacer ring 9, roller guide pin 10, roller guide pin 11 and optical system, wherein, focusing drawtube 2 is connected with guide cylinder 4 by multi-step thread, and its anglec of rotation size is controlled by focusing banking stop 3; The outer cover of guide cylinder 4 is equipped with curve tube 5, be connected zoom lens barrel 7 and compensation lens barrel 8 respectively by roller guide pin 6 and roller guide pin 11, rotate curve tube 5, each roller guide pin is moved along separately curved groove respectively, and drive zoom lens barrel 7 moves with compensation lens barrel 8, the effect of roller guide pin 10 is to guarantee when rotating curve tube 5 that itself and guide cylinder 4 do not produce to move axially, and is stable with these image planes that guarantee camera lens.Optical system in the DLP Zooming-projection camera lens of the present utility model adopts 10 spherical lens structures, includes only balsaming lens L7, a L8 in the system, be in the light hurdle after.This camera lens adopts conventional mechanical type compensation cam mechanism, can organize U1 by focusing for the projected image of different distance realizes along the focusing that moves forward and backward of optical axis, and guaranteeing that along moving forward and backward of optical axis image planes are stable by compensation group U3, total system is negative-negative-eurymeric structure.Fig. 2 is short focus optical system figure, among the figure S4W, S10W, Lkw be illustrated respectively in short when burnt interval between interval, zoom group U2 and the compensation group U3 between focusing group U1 and the zoom group U2 and back work distance from; Fig. 3 is long focus optical system figure, among the figure S4T, S10T, LkT be illustrated respectively in when long burnt interval between interval, zoom group U2 and the compensation group U3 between the focusing group U1 and zoom group U2 and back work distance from; As can be seen, the utility model is three groups of zoom system, pancreatic systems that relatively move, and wherein, focusing group U1 is asynchronous moving, and realizes zoom simultaneously when focusing, but makes simplified structure like this, reduces cost.In addition, light beam is no longer directly forming real image through conventional back fixed lens group on chip behind over-compensation group U3, and therefore, the focal length of compensation group U3 just is necessary for, and promptly total system is negative-negative-eurymeric structure, like this can be so that structure is further compact.

Zoom lens focusing group U1 comprises 2 negative lenses, i.e. L1 and L2 constitute by the crown glass of the low chromatic dispersion of low-refraction, and its effect is to produce an object virtual image near 2 times of focal lengths of object space of zoom group U2.Zoom group U2 is made up of 3 lens, i.e. 2 positive lens L3, L4 and 1 negative lens L5, wherein lens L4 is in the abnormality district of aberration, can be beneficial to guarantee image quality in, make structure compact more.Compensation group U3 is made up of 4 positive lens L6, L7, L9, L10 and a negative lens L8, can guarantee that by the collocation of the correspondence of positive negative lens the aberration that moves forward and backward lens combination can correct alone as far as possible, constitute one by global face optical system and reach the zoom lens of satisfied image quality, picture element that it is more helped in the zoom process is stable.In order not allow the aperture of lens of rear end too big, system Guang Lan is arranged on rear portion (Fig. 2, shown in Figure 3 of camera lens

), otherwise, satisfy little this requirement of rear portion aperture of lens, it is very difficult that the rectification of aberration becomes, and certainly, can also make that the track of light beam is more level and smooth by suitably strengthening the bore of focusing group U1.

The focusing group U1 that light is had a disperse function is imaged on remote thing near the position 2 times of focal lengths of object space of zoom group U2, make zoom group U2 be in magnification, help for realizing that certain zoom ratio is unlikely to the long total system volume that makes of displacement of lens combination excessive near-1 the position.

In order to make Zooming-projection camera lens clear in different projector distance imagings, the focal power control that is distributed in focusing group U1 and zoom group U2 is wanted rationally should satisfy following inequality:

0.85＜|f1/f2|＜1.15

Wherein, f1 is the combined focal length of focusing group U1, and f2 is the combined focal length of zoom group, if exceed this scope, and the just difficult control of the aberration of other focal position.

The structural parameters of the utility model Zooming-projection camera lens are as follows:

FNO 2.35

DIM M

WL 640.0550.0440.0

REF 2

WTW 111

XRI 0.00.00.00.00.00.00.00.00.00.0

YRI 1.072.34.15.87.28.18.99.610.210.7

WTF 1.01.01.01.01.01.01.01.01.01.0

VUY 0.00.00.00.00.00.00.00.00.00.0

VLY 0.00.00.00.00.00.00.00.00.00.0

SO 0.02000.0

S 53.1012.0QK3_CHINA

S 25.355.08846018472

THC?0

S 88.231.5QK3_CH worker NA

S 29.023.023692182

THC?0

S -269.7854.9LAC12_HOYA

CCY 0

S -35.3080.2

S 36.3053.55NBFD15_HOYA

CCY?0

S 291.071.39747856565

THC 0

S -59.981.5FD6_HOYA

S 20.376.50430574425

THC?0

S 23.014.37FD6_HOYA

S -235.010.07

S 0.01.11

STO

S-37.6173.25LAK4_CH worker NA

S-20.281.5ZF4_CH worker NA

S 35.3760.727374373326

THC?0

S 774.3863.55LAF2_HOYA

CCY 0

S -25.030.2

S 52.12.6LAK7_CH worker NA

S -60.91.11

S 0.01.05B1063_CORNFR

S 0.028.2466889501

THC?0

S 0.00.052

SI 0.00.0

ZOO 3

ZOO FNO?2.352.392.43

ZOO THI?S?423.02419.37416.0

ZOO THC?S4000

ZOO THI?S2228.24728.9229.603

ZOO THC?S22000

ZOO THI?S106.5046.6246.747

ZOO THC?S10000

Following table is the chromatic longitudiinal aberration of system when the length focal length

Field is the visual field coordinate of complete relatively visual field in the table, and R is the ratio chromatism, of long wave and reference light, unit: micron, B is the ratio chromatism, of shortwave and reference light, unit: micron.

Referring to Fig. 4, Fig. 5, be that zoom lens of the present utility model is at short burnt, long burnt ray trajectory figure; Fig. 4 is short burnt ray trajectory figure, and Fig. 5 is long burnt ray trajectory figure.

Referring to Fig. 6, Fig. 7, be the curvature of field and the distortion curve figure of zoom lens of the present utility model short Jiao, long Jiao, Fig. 6 is the short burnt curvature of field and distortion curve figure, Fig. 7 is the burnt curvature of field and distortion curve figure of length.

Referring to Fig. 8, Fig. 9, be that zoom lens of the present utility model is burnt at weak point, the burnt transfer curve figure at 461p/mm of length, Fig. 8 is short Jiao's transfer curve figure, Fig. 9 is long Jiao's transfer curve figure.

Referring to Figure 10, Figure 11, be the vertical axial aberration curve map of zoom lens of the present utility model short Jiao, long Jiao, Figure 10 is short burnt vertical axial aberration curve map, Figure 11 is the burnt vertical axial aberration curve map of length.

Referring to Figure 12, Figure 13, be the point range figure of zoom lens of the present utility model short Jiao, long Jiao, Figure 12 is short burnt point range figure, Figure 13 is the burnt point range figure of length.

Claims (7)

1. DLP Zooming-projection camera lens, it is characterized in that: the optical system in the camera lens is made up of the zoom group [U2] of focusing group [U1] with negative power and negative power and the compensation group [U3] of positive light coke, focusing group [U1] zoom group [U2] and compensation group [U3] along optical axis from screen side to the picture planar side series arrangement, wherein, zoom group [U2] and compensation group [U3] from wide-angle side to the end of dolly-out,ing dolly-back along the optical axis realization zoom that relatively moves, the combined focal length of focusing group is f1, the focal length of zoom group is f2, both opposite in signs, and satisfy following inequality: 0.55＜| f1/f2|＜0.72.

2. DLP Zooming-projection camera lens according to claim 1 is characterized in that: described focusing group [U1] is made up of negative lens [L1] and negative lens [L2] to the image planes direction from screen side, and its combined focal length is for negative.

3. DLP Zooming-projection camera lens according to claim 1 is characterized in that: described zoom group [U2] is made up of positive lens [L3], positive lens [L4] and negative lens [L5] to the image planes direction from screen side, and total focal length of zoom group [U2] is for negative.

4. DLP Zooming-projection camera lens according to claim 3 is characterized in that: the screen side surface of second positive lens of screen side [L4] is to the bending of image planes direction in the described zoom group [U2].

5. DLP Zooming-projection camera lens according to claim 1, it is characterized in that: described compensation group [U3] is made up of positive lens [L6], positive lens [L7], negative lens [L8], positive lens [L9], positive lens [L10] to the image planes direction from screen side, wherein, positive lens [L7] and negative lens [L8] are cemented doublet, its cemented surface bends towards the light hurdle, and total focal length of compensation group [U3] is for just.

6. DLP Zooming-projection camera lens according to claim 5 is characterized in that: the positive lens in the described cemented doublet [L7] is the crown glass lens, and negative lens [L8] is concave-concave flint glass lens.

7. DLP Zooming-projection camera lens according to claim 1 is characterized in that: each lens in described focusing group [U1], zoom group [U2] and the compensation group [U3] are spherical lens, and the sum of its lens is 10.

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